TECHNICAL FIELD
[0001] The present invention relates to a process for desorption, e.g. desorbing a solvent,
from a bedding of adsorbent material, e.g. activated carbon, by means of a hot gas
flow, e.g. air, so that a wave of concentration induces, which goes through the bedding
by means of the hot gas flow. The invention also relates to an apparatus, in which
the process will be carried out.
BACKGROUND TO THE INVENTION AND PRIOR ART
[0002] Desorption apparatuses are known e.g. from WO-A-89/10 189 and DE-C-3 141 484.
[0003] Cleaning out solvent from contaminated air by means of adsorption and subsequent
desorption of matter(s) is a well known engineering practice. As adsorbent material,
activated carbon is often used. To regenerate the activated carbon, the temperature
is raised and volatile solvents evaporate. For heating purpose a direct inlet of a
hot gas stream which can be condensable, e.g. steam, or non-condensable, e.g. nitrogen,
can be used. Heating can also be caused indirectly via heating surfaces, at which
the means of heating will be kept separate from the adsorbent material.
[0004] Adsorption beddings can be solid, which is the most common construction. During continuous
operation, the air must change over to a new bedding when the adsorption capacity
of the working bedding is exceeded. The adsorption bedding can also be rotating and
segmented, thus air to be purified passes through one segment while strip gas passes
through another segment. In this manner, a simultaneous purification of contaminated
air and a regeneration of the adsorbent is taking place. A drawback with this construction
is that it is expensive and bulky.
[0005] At desorption in a solid bedding with a hot, non-condensable strip gas a heat front
with steep temperature gradient will slide through the bedding. If the gas flow is
uniform the heat front will be parallel to the frontal surface of the bedding, that
is, the surface through which the strip gas penetrates into the bedding. In the flow
direction, in the front of the heat front, an area will form in which the solvent
concentration in the activated carbon increases due to readsorption of desorbate,
which has desorbed behind the heat front. Thus, in front of the heat front a concentration
wave will form, that is, an area with increased solvent concentration. When this concentration
wave reaches the outer surface of the bedding, the concentration in the strip gas
leaving the bedding will rise to a level that can be many times higher than the average
concentration in the outgoing strip gas during the phase of desorption.
[0006] The varying concentration of solvent in the outgoing strip gas will in a construction
with solid bedding lead to that air only under certain conditions can be used as strip
gas. A risk arises that the solvent concentration, during a certain part of the phase
of desorption, can become an explosion hazard. Due to the explosion risk, constructions
with solid bedding often require nitrogen or another relatively expensive inert gas
to be used as strip gas.
[0007] At the same time new laws and regulations have resulted in higher demands for purification
of solvent-contaminated exhaust air as well as increasing efficiency of gas purifying
equipment. Hence, it is important that apparatuses for cleaning can be made small,
effective and inexpensive to run.
BRIEF DISCLOSURE OF THE INVENTION
[0008] The purpose with the invention is to offer an apparatus which allows disadvantages
in known technology to be eliminated.
[0009] This assignment has been solved through an apparatus at which the concentration wave
is controlled to successively reach the gas outlet of the bedding as disclosed in
the wording of independent claim 1.
[0010] Further advantages and distinctive features of the invention will be evident in the
following description and the appending claims.
[0011] In the description, the use of the apparatus of the invention will be illustrated
by example of desorption of adsorbate. It shall be realized that the principles of
the invention are applicable also for driving away absorbate or in a combination adsorbate
and absorbate.
BRIEF DESCRIPTION OF DRAWINGS
[0012] In the following description reference will be made to the accompanying drawings,
in which
- Fig. 1
- shows an explanatory sketch, illustrating devices and components at an apparatus for
gas cleaning and desorption of adsorbate according to a first preferred embodiment
of the invention,
- Fig. 1A
- schematically shows a perspective view of an element of the bedding which is a part
of the apparatus in Fig. 1,
- Fig. 2
- shows a cross-section of an adsorbent bedding according to a second embodiment of
the invention, which is being used in the exemplified experiments,
- Fig. 3
- shows a cross-section of an adsorbent bedding not according to the invention, in which
the bedding elements have the shape of rectangular parallelepipeds,
- Fig. 3A
- shows a cross-section along the line A-A in Fig. 3,
- Fig. 3B
- shows a cross-section along the line B-B in Fig. 3A,
- Fig. 3C
- shows the same view as Fig. 3B but where a throttle to throttle down the strip gas
is inclined,
- Fig. 4
- shows a cross-section of an adsorbent bedding according to a third embodiment, illustrating
known technology, and which is used in comparison experiments, and
- Fig. 5
- constitutes a graph showing the content of solvent in the gas flow of desorption in
the outlet from purifying beddings according to the mentioned first, second and third
embodiments.
DESCRIPTION OF EMBODIMENTS
[0013] In Fig. 1 an inlet for contaminated air is designated 1, and outlet for purified
air designated 2, and bedding elements designated 3a and 3b, respectively. All together
they constitute a bedding 4 for purifying contaminated air. A throttle valve 15 is
provided in the outlet 2 for purified air and a throttle valve 16 is provided in the
inlet for contaminated air.
[0014] Each bedding element 3a, 3b has the shape of a hexahedron with three rectangular
faces 3c, 3d, 3e, one square face 3f and two trapeziformed faces 3g with two right-angled
corners. One of the rectangular faces - face 3e - inclines compared to the square
outer face 3f forming a non-right-angle with both the other rectangular faces 3c,
3d, which are forming topface and bottomface in the element. The inclination between
the surfaces 3e and 3f is such that the relation between the longer and the shorter
parallel edges of the trapeziformed face 3g is at least equal to 1.5 and at the most
equal to 3.
[0015] The bedding 4 is formed by the two bedding elements 3a, 3b through an arrangement
where the inclining faces 3e are facing against each other, in reversed order, so
that the bedding 4 obtains the shape of a parallelepiped. The two elements 3a, 3b
are separated by a disc-shaped slot 7. It is to be percieved that this has the same
inclination as the faces 3e. Preferably the two bedding elements 3a, 3b are similar,
and the slot 7 will range inclinated and symmetrical throughout the bedding 4. The
bedding elements 3a, 3b contain granular adsorbent material, e.g. activated carbon
14. Other adsorbent materials and/or absorbent materials can be used as well, e.g.
zeolites, adsorbent polymers, ion-exchangers and corresponding material.
[0016] The outer faces 3f and inner faces 3e (situated opposite to each other) of the bedding
elements 3a, 3b can be made out of perforated plate, net or similar allowing passage
of contaminated air for purification and strip air for regeneration of the adsorbent
material 14. Other faces 3c, 3d, 3g are tight.
[0017] A suction fan 18 is arranged in the outlet 2 for purified air. The suction fan 18
will establish necessary negative pressure to lead the air stream in the requested
direction from the source of rough gas, that is, through inlet 1 to a first air box
17a on the inlet side of the bedding 4, from there through the first bedding element
3a, through the slot 7 and through the second bedding element 3b to a second air box
17b on the outlet side of the bedding 4 and to the outlet 2.
[0018] A burner is designated 5. Solvent, removed from the bedding 4 via the slot 7, which
via a pipe is connected with the burner 5, will combust in the burner. A strip gas
fan is provided in the pipe 8. The strip gas fan 13 is arranged so that during regeneration
a necessary negative pressure establishes to suck hot strip gas from an inlet 12 for
strip gas, via the pipes 9a, 9b to the air boxes 17a, 17b, and from the air boxes
17a, 17b through the bedding elements 3a and 3b, respectively, and to the slot 7,
where the two gas flows join. From the slot 7 the resulting gas flow goes through
the pipe 8 to the burner 5. The feed of strip gas to the air boxes 17a, 17b can be
interrupted and regulated with valves 11a, 11b in the pipes 9a, 9b. A heating device
for strip gas in the pipe 12 is designated 20.
[0019] The device according to Fig. 1 is part of a regenerating system for gas purifying
based on adsorption in a bedding with granular adsorbent material, at which the regeneration
of the bedding takes place through desorption of adsorbate by means of heating and
venting the adsorbent material. This heating and venting takes place therein that
hot strip gas is led through the bedding. The equipment can for instance be used for
air purification during one shift per twenty-four hours, while regeneration of the
adsorbent material takes place during another shift.
[0020] During the phase of air purification the valves 15 and 16 are open, and the valves
11a, 11b and 10 for strip air are kept closed. The contaminated air is brought into
the device via the pipe 1 and is led with retained flow direction through the bedding
4 to the outlet 2 for purified air. Air is cleaned therein that impurities, for instance
solvent, are adsorbed by the adsorbent material 14 in the bedding 4. The bedding 4
has a limited adsorption capacity. Hence, the adsorbent material must be generated
at even intervals according to a prior decided cycle or latest when the adsorption
capacity of the bedding has reached saturation. During the phase of regeneration,
the valves 15 and 16 are kept closed, while the valves 11a, 11b and 10 are open. Strip
air is sucked through the system by means of the fan 13. From the pipe 12 the hot
air divides into two flow fractions. One flow is led via the pipe 9a and the valve
11a into the first air box 17a. The other flow is led via the pipe 9b and the valve
11b into the air box 17b. By means of the valves 11a, 11b the stream of strip air
going to their respective air boxes can be regulated. From the air boxes 17a, 17b
the hot strip air will be sucked through the hexahedron shaped bedding element 3a
and 3b, respectively, to the slot 7. From there the rejoined flow of strip air will
be sucked through the pipe 10 to the burner 5.
[0021] Owing to that the bedding elements 3a, 3b in cross-section have the shape of a trapezium,
the strip air will have a varying distance to pass through each bedding element, dependent
of the area in which the air penetrates through the bedding material. In the lower
part of the bedding element 3a, and in the upper parts of the bedding element 3b,
respectively, the strip air has a relatively short path to go through the bedding
material from each air box 17a, 17b to the slot 7, while strip air in the upper parts
of the bedding element 3a, and in the lower parts of the bedding element 3b, respectively,
has a relatively longer path to go through the bedding material. The result is that
the heat front which forms in the bedding material due to the hot strip air successively
reaches the slot 7, starting in the "thinner" sections of the bedding elements 3a,
3b. Therefore the slot 7 will receive the released combustible contaminants, for instance
solvents, at a moderate concentration during a proportionately long time, which is
advantageous, since explosion hazard thereby can be avoided. Thus, the burner 5 can
receive strip air with suitable proportion of solvent without risk. Through combustion
in burner 5 the evaporated solvent or corresponding contaminant will be destroyed.
[0022] Consequently, through the invention one achieves a high uniform concentration of
solvent in the outgoing strip gas during regeneration which is important for the combustion
step. Particularly important is that fumes of solvent in the strip gas will not reach
a concentration where explosion hazard exists. This is thus achieved therein that
the concentration wave in front of the advancing heat front successively reaches the
bedding surface on the outlet side, in this case the faces 3e, situated opposite of
the slot 7, that is, the concentration wave passes out through a bedding surface 3e
which is not parallel to the wave itself and consequently not parallel to the heat
front.
[0023] During the regeneration phase the two bedding elements 3a and 3b are connected in
parallel, wherein the desired effect with a successive outlet of the concentration
wave is achieved. However, during the purification phase the bedding elements 3a and
3b are connected in series, in which case the bedding 4 works as a conventional solvent
filter shaped as a rectangular parallelepiped, which is favourable because it allows
an optimal utilization of the adsorbent material.
[0024] In Fig. 2 an embodiment is illustrated where the bedding 4' has the shape of a hexahedron
with in principle the same design as one of the bedding elements 3a, 3b in the previous
embodiment. In this case the most narrow part of the bedding must be dimensioned with
consideration of desired capacity over the bedding, which involves that the thicker
parts of the bedding must be overdimensioned. That means that the adsorbent material
cannot be utilized optimally in this case. This embodiment is in other words not the
best one. Not even during regeneration can it be achieved as high levelling out of
the concentration wave as in the previous embodiment. Yet, compared to a completely
parallelepipedically shaped bedding, significant advantages are achieved.
[0025] Fig. 3 shows an embodiment, not according to the invention, at which the bedding
elements have the shape of rectangular parallelepipeds. The device in Fig. 3 corresponds
to a large extent to the device in Fig. 1. Thus, the device in Fig. 3 is equipped
with valves 11a'', 11b'' and 10'', pipes 9a'', 9b'' and 8'', throttle valves 15''
and 16'' and an outlet for purified air 2'', which all have their equivalent in the
device in Fig. 1. The device in Fig. 3 has also two bedding elements 3a'', 3b'', but
in distinction to the device in Fig. 1, each one of them has the shape of a rectangular
parallelepiped.
[0026] Between the bedding elements 3a'', 3b'' there is a space which is divided into vertical
ducts 27a, b, c, d, e with rectangular cross-section. The ducts are made of vertical
rectangular plates, arranged between the bedding elements 3a'', 3b''. At the lower
ends of the ducts 27a, b, c, d, e, a suction box 24 for strip air is provided. The
box is connected with the suction fan 13'' via a pipe 8'', equipped with a valve 10''.
[0027] At the lower ends of the ducts 27a, b, c, d, e, a throttle 28 is arranged. The throttle
28 can be made of an angle bar that can be turned around a vertical axis 25 and be
positioned in different angles of rotation by means of a screw or similar means. In
the position shown in Fig. 3B, the strip air is damped equally much in each of the
ducts 27a, b, c, d, e. If the throttle 28 is twisted to the position shown in Fig.
3C, the strip air will be damped maximally through the duct 27a and not damped at
all through the duct 27e.
[0028] During the phase of air purification the throttles 15'', 16'' are open and the valves
10'' and 11a'', 11b'' are closed. The fan 18'' then sucks poluted air through the
bedding elements and in a horizontal direction through the ducts 27a, b, c, d, e.
[0029] During the regeneration of the bedding elements the throttles 15'', 16'' and the
valves 10'' and 11a'', 11b'' are opened, wherein strip air is sucked through the bedding
elements 3a'', 3b'' towards the ducts 27, b, c, d, e. The inclination of the throttle
28 causes a throttle down in the passage between the ducts 27 and suction box 28.
This throttling down caused by the inclination shown in Fig. 3C has the largest effect
in duct 27e. Ducts laying inbetween receive a successively decreasing throttling in
direction from duct 27a to duct 27e. The pressure drop due to throttling down is large
compared to the pressure drop in the ducts 27a, b, c, d, e meaning that the amount
of air going through each single duct 27a, b, c, d, e will depend on how far the throttling
down has gone. By those ducts 27a, b, c, d, e having a passage, with large cross-section,
from the duct to the box 24 the amount of air passing will be relatively large and
by ducts having a smaller cross-section the corresponding amount of air passing will
be smaller. Since the ducts 27a, b, c, d, e have the same cross-section, the strip
air speed in each duct 27a, b, c, d, e will vary with the cross-section in the passage
to the box 24. When increasing the cross-section, the airflow passing the duct increases
and with that the speed of strip air. In Fig. 3A there are arrows V
a, V
b, V
c, V
d, V
e to show how the strip air speed increases stepwise from duct 27a to duct 27e with
an inclination of the throttle 28 as shown in Fig. 3C.
[0030] Through the parts of the bedding elements 3a'', 3b'' connected to the duct 27e, a
larger amount of strip air will pass than through the parts of the bedding element
connected to the duct 27A. The heat transfer to those parts of the bedding elements
passed by strip air, led to duct 27e, will be larger than the heat transfer to the
other parts of the bedding elements. The heat front going through the ducts 27a, b,
c, d e will thus travel fastest in those parts of the bedding elements passed by strip
air going to the duct 27e. The heat front going through each bedding element will
thus successively reach duct 27a, b, c, d, e reaching the duct 27e first and the duct
27a last, if the damper 28 is adjusted as shown in Fig. 3C. Thus, the heat front is
controlled to successively reach the gas outlet of the bedding.
[0031] One can conceive other embodiments within the frame of the invention. In the examples
above, the bedding elements had flat surfaces. The strip air penetration surface can
also be bent, e.g. a circular cylindrical mantel surface. The heat front will then
be mainly circular cylindrical with an increasing or decreasing bending radius, which
in turn depends of whether the penetration surface is concave or convex. In that case
it can be arranged that the concentration wave successively reaches a circular cylindrical
bedding surface, if the generated circles from the mantel surfaces are not concentrical.
Also other modifications than the above mentioned are possible without deviation from
the general principles of the invention, nor that the modified device falls outside
the limits of the appending claims.
DISCLOSURE OF EXPERIMENTS
[0032] In an experimental plant, set up in a way that different types of purifying beddings
can be installed, experiments were carried out separating solvent from gas. The experiments
included a phase of adsorption, during which solvent-contaminated gas was led through
the purifying bedding and solvent was adsorbed by the adsorbent material, and a phase
of desorption at which a hot air stream was led through the bedding and solvent was
desorped and consequently removed from the adsorbent. The experiments were carried
out with three different types of purifying beddings, here designated I, II and III.
[0033] The bedding of type I corresponded in its general construction to the bedding 4 in
Fig. 1. The bedding of type I had consequently the shape of a rectangular parallelepiped,
in this case with the dimensions 0.5 m x 0.5 m x 0.15 m and was divided into two mutally
alike bedding elements 3a, 3b. The slot 7 between the bedding elements was arranged
inclined in relation to the square outer surfaces 3f of the bedding. The parallel
edges on the side of the bedding elements 3g (Fig. 3A) was 0.05 and 0.1 m, respectively.
The adsorption flow as well as the desorption flow were led through the bedding perpendicularly
to the square surfaces 3f. The adsorption flow, though, was led from one square surface
to the other when passing the bedding elements 3a, 3b, connected in series, and the
slot 7. The desorption flow, on the other hand, was parted into two partial flows,
each passing one of the connected bedding elements 3a, 3b, connected in parallel,
into the slot 7, reuniting into one outgoing desorption flow.
[0034] The bedding of type II was not parted into separate bedding elements. It consisted
of a homogeneous hexahedron-shaped bedding 4' with a shape that was described with
reference to Fig. 2. The square side had the dimension 0.5 m x 0.5 m. The smallest
rectangular face, the top face with reference to Fig. 2, had the measures 0.5 m x
0.15 m. The largest rectangular face, the face heading against the air box 17a', Fig.
2, inclined in relation to the square outer face of the bedding, that is, the face
heading against the other air box 17b. The inclination was the same as for the bedding
of type I above. The adsorption flow as well as the desorption flow was led through
the bedding perpendicularly to the square surface constituting the inlet for the flow,
that is, by first passing through the air box 17b'. The outlet surface was the surface
that faced the air box 17a', Fig. 2.
[0035] The bedding of type III is designated 4'' in Fig. 4. It consisted according to conventional
technology of a bedding element shaped as a rectangular parallelepiped with the dimensions
0.5 x 0.5 x 0.15 m. The adsorption flow and the desorption flow was led through the
bedding perpendicularly to the square surfaces.
Example 1: Purification bedding type I
[0036]
| Adsorption: |
Air 1000 m3/h during |
8 h |
| Solvent content |
0.1 g/m3 |
| Solvent amount |
0.8 kg |
| Solvent: |
Xylene |
50 % |
| Styrene |
50 % |
| Desorption: |
Air 50 m3/h |
|
| Time for desorption |
4 h |
| Solvent amount |
0.76 kg |
| Maximum solvent concentration in desorption flow |
5 g/m3 |
Example 2: Purification bedding type II
[0037]
| Adsorption: |
Air 1000 m3/during |
8 h |
| Solvent content |
0.1 g/m3 |
| Solvent amount: |
0.8 kg |
| Solvent: |
Xylene |
50 % |
| Styrene |
50 % |
| Desorption: |
Air 50 m3/h |
|
| Time for desorption |
4 h |
| Solvent amount |
0.76 kg |
| Maximum solvent concentration in desorption flow |
6 g/m3 |
Example 3: Purification bedding type III
[0038]
| Adsorption: |
Air 1000 m3 /h during |
8 h |
| Solvent content |
0.1 g/m3 |
| Solvent amount |
0.8 kg |
| Solvent: |
Xylene |
50 % |
| Styrene |
50 % |
| Desorption: |
Air 50 m3/h |
|
| Time for desorption |
4 h |
| Solvent amount |
0.76 kg |
| Maximum solvent concentration in desorption flow |
15 g/m3 |
[0039] The graph in Fig. 5 shows the content of solvent in the desorption flow at the outlet
of the purifying beddings of type I, II and III as a function of time passed since
beginning of desorption. From the graph it is evident that the most favourable flow
is achieved with purifying bedding of type I. When one has an adsorption bedding shaped
as a rectangular parallelepiped, as in the bedding 4'', one achieves a marked concentration
peak when the concentration wave penetrates through the bedding reaching the outlet.
The phenomena can be avoided by use of this invention, and in particular if it is
given the embodiment illustrated in Fig. 1 and described above.
1. Vorrichtung zur Durchführung eines Verfahrens zur Desorption eines Lösungsmittels
aus einem Bett eines Adsorptionsmaterials, wobei die Vorrichtung folgendes umfaßt:
ein Bett (4) aus Adsorptionsmaterial (14), das eine Bettfläche (3f) für den Gaseintritt
und eine Bettfläche (3e) für den Gasaustritt aufweist,
Mittel, die einen heißen Gasstrom veranlassen, das Bett von der Bettfläche (3f) für
den Gaseintritt zur Bettfläche (3e) für den Gasaustritt zu durchlaufen, um eine Lösungsmittelkonzentrationswelle
zu erzeugen, die mittels des heißen Gasstroms durch das Bett gedrückt wird,
wobei die Bettflächen (3f,3e) so angeordnet sind, daß das Bett verschiedene Weglängen
für verschiedene Anteile des Gasstromes bereitstellt, so daß die im Bett vom Gasstrom
erzeugte Konzentrationswelle die Austrittsbettfläche (3e) schrittweise erreicht.
2. Vorrichtung nach Anspruch 1, dadurch gekennzeichnet, daß die Bettfläche (3f) für den
Gaseintritt und die Bettfläche (3e) für den Gasaustritt nicht parallel sind.
3. Vorrichtung nach Anspruch 2, dadurch gekennzeichnet, daß die Bettfläche (3f) für den
Gaseintritt und die Bettfläche (3e) für den Gasaustritt flach sind.
4. Vorrichtung nach Anspruch 3, dadurch gekennzeichnet, daß die Bettflächen miteinander
einen Winkel bilden, so daß das Verhältnis zwischen dem längsten Weg des Gasstroms,
der von der Bettfläche (3f) für den Gaseintritt zu der Bettfläche (3e) für den Gasaustritt
verläuft, und dem entsprechenden kürzesten Weg mindestens 1,3 und höchstens 3 beträgt.
5. Vorrichtung nach Anspruch 4, dadurch gekennzeichnet, daß das Verhältnis zwischen 1,6
und 2,0 liegt.
6. Vorrichtung nach Anspruch 1, dadurch gekennzeichnet, daß das Bett wenigstens zwei
Bettelemente (3a,3b) enthält, die während der Adsorptionsphase in Reihe geschaltet
sind, wogegen die Bettelemente während der Desorptionsphase parallel geschaltet sind,
und daß sich die Weglängen verschiedener Anteile eines die Bettelemente durchlaufenden
Abziehgases unterscheiden.
1. Appareil pour la mise en oeuvre d'un procédé de désorption d'un solvant à partir d'une
structure en lit de matériau adsorbant, l'appareil comprenant :
une structure en lit (4) de matériau adsorbant (14) présentant une surface en lit
(3f) pour l'admission de gaz et une surface en lit (3e) pour l'évacuation de gaz ;
des moyens pour forcer un écoulement de gaz chaud à traverser la structure en lit
depuis la surface en lit (3f) pour l'admission de gaz en direction de la surface en
lit (3e) pour l'évacuation de gaz afin d'induire une onde de concentration de solvant
qui est forcée à traverser la structure en lit au moyen de l'écoulement de gaz chaud
;
dans lequel lesdites surfaces en lit (3f 3e) sont agencées de façon que la structure
en lit offre des longueurs de trajets différentes pour les différentes fractions de
l'écoulement de gaz, afin que l'onde de concentration induite par l'écoulement de
gaz dans la structure en lit atteigne la surface en lit côté évacuation (3e) successivement.
2. Appareil selon la revendication 1, dans lequel ladite surface en lit (3f) pour l'admission
de gaz et ladite surface en lit (3e) pour l'évacuation de gaz sont non parallèles.
3. Appareil selon la revendication 2, dans lequel ladite surface en lit (3f) pour l'admission
de gaz et ladite surface en lit (3e) pour l'évacuation de gaz sont plates.
4. Appareil selon la revendication 3, dans lequel les surfaces en lit forment, l'une
avec l'autre, un angle tel que la relation entre le trajet d'écoulement de gaz le
plus long, allant de la surface en lit (3f) pour l'admission de gaz en direction de
la surface en lit (3e) pour l'évacuation de gaz, et le trajet le plus court correspondant
est au moins égale à 1,3 et au plus, égale à 3.
5. Appareil selon la revendication 4, dans lequel la relation est comprise entre 1,6
et 2,0.
6. Appareil selon la revendication 1, dans lequel structure en lit contient au moins
deux éléments mis en lit (3a, 3b) qui sont connectés en série pendant la phase d'adsorption,
tandis que les éléments en lit, pendant la phase de désorption, sont connectés en
parallèle, et dans lequel la longueur de trajet différera entre les fractions de gaz
rectifiées différentes qui traversent les éléments mis en lit.